Title

Probabilistic Modeling Of Scene Dynamics For Applications In Visual Surveillance

Keywords

Kernel density estimation; Machine learning; Markov Chain Monte Carlo; Markov processes; Metropolis-Hastings; Tracking; Vision and scene understanding

Abstract

We propose a novel method to model and learn the scene activity, observed by a static camera. The proposed model is very general and can be applied for solution of a variety of problems. The motion patterns of objects in the scene are modeled in the form of a multivariate nonparametric probability density function of spatiotemporal variables (object locations and transition times between them). Kernel Density Estimation is used to learn this model in a completely unsupervised fashion. Learning is accomplished by observing the trajectories of objects by a static camera over extended periods of time. It encodes the probabilistic nature of the behavior of moving objects in the scene and is useful for activity analysis applications, such as persistent tracking and anomalous motion detection. In addition, the model also captures salient scene features, such as the areas of occlusion and most likely paths. Once the model is learned, we use a unified Markov Chain Monte Carlo (MCMC)-based framework for generating the most likely paths in the scene, improving foreground detection, persistent labeling of objects during tracking, and deciding whether a given trajectory represents an anomaly to the observed motion patterns. Experiments with real-world videos are reported which validate the proposed approach. © 2009 IEEE.

Publication Date

5-7-2009

Publication Title

IEEE Transactions on Pattern Analysis and Machine Intelligence

Volume

31

Issue

8

Number of Pages

1472-1485

Document Type

Article

Personal Identifier

scopus

DOI Link

https://doi.org/10.1109/TPAMI.2008.175

Socpus ID

67650450207 (Scopus)

Source API URL

https://api.elsevier.com/content/abstract/scopus_id/67650450207

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